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Theory of quantum path computing with Fourier optics and future applications for quantum supremacy, neural networks and nonlinear Schrödinger equations

عنوان	Theory of quantum path computing with Fourier optics and future applications for quantum supremacy, neural networks and nonlinear Schrödinger equations
نویسنده	Gülbahar, Burhan
تاریخ انتشار:	2020-07-03
محل انتشار	- Nature Research
نوع	دوره ای
زبان	انگلیسی
دیجیتال	بله
نسخه خطی	خیر
کتابخانه:	دانشگاه اوزیغین
شناسه دارایی کتابخانه	2045-2322
شماره ثبت	9e44350d-dec6-4192-8e3a-82dbd44a4ffa
محل کتابخانه	Electrical & Electronics Engineering
تاریخ	2020-07-03
متن نمونه	The scalability, error correction and practical problem solving are important challenges for quantum computing (QC) as more emphasized by quantum supremacy (QS) experiments. Quantum path computing (QPC), recently introduced for linear optic based QCs as an unconventional design, targets to obtain scalability and practical problem solving. It samples the intensity from the interference of exponentially increasing number of propagation paths obtained in multi-plane diffraction (MPD) of classical particle sources. QPC exploits MPD based quantum temporal correlations of the paths and freely entangled projections at different time instants, for the first time, with the classical light source and intensity measurement while not requiring photon interactions or single photon sources and receivers. In this article, photonic QPC is defined, theoretically modeled and numerically analyzed for arbitrary Fourier optical or quadratic phase set-ups while utilizing both Gaussian and Hermite-Gaussian source laser modes. Problem solving capabilities already including partial sum of Riemann theta functions are extended. Important future applications, implementation challenges and open issues such as universal computation and quantum circuit implementations determining the scope of QC capabilities are discussed. The applications include QS experiments reaching more than 2(100) Feynman paths, quantum neuron implementations and solutions of nonlinear Schrodinger equation.
DOI	10.1038/s41598-020-67364-0
Cilt	10

مشاهده در منبع دانشگاه اوزیغین دانشگاه اوزیغین - موتور جستجوی نسخه های خطی عثمانی

دانشگاه اوزیغین

Theory of quantum path computing with Fourier optics and future applications for quantum supremacy, neural networks and nonlinear Schrödinger equations

نویسنده Gülbahar, Burhan

تاریخ انتشار 2020-07-03

محل انتشار - Nature Research

نوع دوره ای

زبان انگلیسی

دیجیتال بله

نسخه خطی خیر

کتابخانه دانشگاه اوزیغین

شناسه دارایی کتابخانه 2045-2322

شماره ثبت 9e44350d-dec6-4192-8e3a-82dbd44a4ffa

محل کتابخانه Electrical & Electronics Engineering

تاریخ 2020-07-03

متن نمونه The scalability, error correction and practical problem solving are important challenges for quantum computing (QC) as more emphasized by quantum supremacy (QS) experiments. Quantum path computing (QPC), recently introduced for linear optic based QCs as an unconventional design, targets to obtain scalability and practical problem solving. It samples the intensity from the interference of exponentially increasing number of propagation paths obtained in multi-plane diffraction (MPD) of classical particle sources. QPC exploits MPD based quantum temporal correlations of the paths and freely entangled projections at different time instants, for the first time, with the classical light source and intensity measurement while not requiring photon interactions or single photon sources and receivers. In this article, photonic QPC is defined, theoretically modeled and numerically analyzed for arbitrary Fourier optical or quadratic phase set-ups while utilizing both Gaussian and Hermite-Gaussian source laser modes. Problem solving capabilities already including partial sum of Riemann theta functions are extended. Important future applications, implementation challenges and open issues such as universal computation and quantum circuit implementations determining the scope of QC capabilities are discussed. The applications include QS experiments reaching more than 2(100) Feynman paths, quantum neuron implementations and solutions of nonlinear Schrodinger equation.

DOI 10.1038/s41598-020-67364-0

Cilt 10